Low noise amplifier

ABSTRACT

A low noise amplifier includes an input matching means of an input stage and an output matching means of an output stage, a common source transistor and a common gate transistor serially connected between the input matching means and the output matching means, a first inductor connected between said common source transistor and common gate transistor a second inductor connected between the common point of said common source transistor and common gate transistor and the output stage of said common gate transistor. Therefore, the low noise amplifier allows the points of Γ opt  and G max  to be closer to each other so that the noise and input gain simultaneous matching is performed, thereby improving the performance.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a low noise amplifier, and more particularly to an improved low noise amplifier.

2. Description of the Prior Art

FIG. 1 is a circuit diagram of a conventional low noise amplifier, which includes input/output matching circuits 10 and 14 and an active device 12.

The noise figure of the low noise amplifier shown in FIG. 1 is expressed in the following relationship: ##EQU1## where NF_(min) represents a minimum noise figure, R_(n) represents a normalized noise resistance, Γ_(opt) represents an optimum noise matching source reflectivity, and Γ_(s) represents a source reflectivity, respectively. These figures are known as noise parameters and may be determined experimentally. Also, NF is a function of Γ_(s). In order to obtain NFrnin, Γ_(s) and rpt should be equal to Γ_(opt). This matching procedure is called a noise matching.

Next, let us consider the power gain of the microwave. There are several gain definitions in the microwave amplifier. Considering a finite S₁₂ of an active device 12 which is quite useful in the microwave frequencies the useful power gain concept for the design of the input match network of the microwave amplifiers is the available power gain G_(A), which is the ratio of the power available from the source to the power available from the network. This is given by ##EQU2## where G_(A) is not a function of the load reflectivity Γ_(L) but a function of Γ_(s) and S parameter of the active device 12. Thus, the process for obtaining the maximum Γ_(s) and G_(A) is called an input power matching.

An output matching circuit 14 of the low noise amplifier can be devised using an operative power gain concept defined by the following equations: ##EQU3## where G_(p) is not a function of Γ_(s) but a function of Γ_(L) and S parameters of the active device 12. Thus, the process for obtaining the maximum Γ_(L) and G_(p) is called an output power matching, to which a general matching technique may be adopted.

Now, let us consider the stability of the microwave amplifiers. The necessary and sufficient conditions for unconditional stability are given in the following equations: ##EQU4## where Δ=S₂₁ S₂₂ -S₁₂ S₂₁.

When a stability factor K of the active device is bigger than 1 the input/output power matching can be obtained but when a stability factor K of the active device is smaller than 1, we cannot have an indefinite matching. This is because the power matching points are placed at an unstable area, which is very usual for the microwave amplifiers. Therefore, the stability procedure is highly required for the power matching. A partially stable or unstable active device can be stabilized by using a loading or feedback technique in an input (or output) stage.

However, an additive stabilizer can considerably reduce the noise performance. Thus, in designing a microwave low noise amplifier, a stabilizing circuit should be carefully selected to avoid undesired addition of noise which may be caused by adding the stabilizer.

In designing the low noise amplifier with the common source single gate electric field effect transistor (or common gate bipolar junction transistor), it is well known that the noise matching for accomplishing NF_(min) is caused by the voltage standing wave ratio (VSWR) or vice versa. This is because the optimum noise matching source reflectivity Γ_(opt) is quite different from the maximum available power gain matching source reflectivity G_(max). Therefore, if the noise matching is performed, the input power matching is not achieved, or vice versa. Thus, it is required to compromise factors among NF, power gain and input VSWR.

However, if Γ_(opt) and G_(max) are able to be matched, then NF_(min), the maximum available power gain and low input VSWR are simultaneously achieved. This is called a noise and input power simultaneous matching.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a low noise amplifier which can perform a noise and input power simultaneousness matching by matching Γ_(opt) and G_(max).

To accomplish the above object, according to a first aspect of the present invention, there is provided a low noise amplifier comprising: an input matching means of an input stage and an output matching means of an output stage; a common source transistor and a common gate transistor serially connected between the input matching means and the output matching means; and a feedback resistor connected between the input matching means and the output matching means.

According to a second aspect of the present invention, there is provided a low noise amplifier comprising: an input matching means of an input stage and an output matching means of an output stage; a common gate transistor connected between the input matching means and the output matching means; and a feedback inductor connected between the input matching means and the output matching means.

According to a third aspect of the present invention, there is provided a low noise amplifier comprising: an input matching means of an input stage and an output matching means of an output stage; a common source transistor and a common gate transistor serially connected between the input matching means and the output matching means; a feedback resistor connected between the input matching means and the output matching means; and inductor connected between the common point of the common source transistor and common gate transistor and the output stage of the common gate transistor.

According to a fourth aspect of the present invention, there is provided a low noise amplifier comprising: an input matching means of an input stage and an output matching means of an output stage; a common source transistor and a common gate transistor serially connected between the input matching means and the output matching means; an inductor connected between a source and a ground of the common source transistor; and a resistor connected between the output stage and ground of the common source transistor.

According to a fifth aspect of the present invention, there is provided a low noise amplifier comprising: an input matching means of an input stage and an output matching means of an output stage; a common source transistor and a common gate transistor serially connected between the input matching means and the output matching means; a first inductor connected between a source and a ground of the common source transistor; and a second inductor connected between the common point of the common source transistor and common gate transistor and the output stage of the common gate transistor.

According to a sixth aspect of the present invention, there is provided a low noise amplifier comprising: an input matching means of an input stage and an output matching means of an output stage; a common emitter transistor and a common base transistor connected in serial between said input matching means and said output matching means; a first inductor connected between an emitter and a ground of said common emitter transistor; and a second inductor connected between the common point of said common emitter transistor and common base transistor and the output stage of said common base transistor.

According to a seventh aspect of the present invention, there is provided a low noise amplifier comprising: an input matching means of an input stage and an output matching means of an output stage; a common emitter transistor and a common base transistor connected in serial between said input matching means and said output matching means; an inductor connected between an emitter and ground of said common emitter transistor; and a resistor connected between the output stage and ground of said common base transistor.

BRIEF DESCRIPTION OF THE DRAWINGS

The above objects, and other features and advantages of the present invention will become more apparent by describing in detail a preferred embodiment thereof with reference to the attached drawings in which:

FIG. 1 is a circuit diagram of a conventional low noise amplifier;

FIGS. 2 through 7 are circuit diagrams illustrating the constructions of conventional low noise amplifiers;

FIG. 8 is a circuit diagram of an active device of a low noise amplifier in accordance with a first embodiment of the present invention;

FIG. 9 is a Smith's chart showing points of Γ_(opt), G_(max) and S₁₁ depending a feedback resistor of a cascode resistive parallel feedback at 4.5GHz;

FIG. 10 is a circuit diagram of an active device of a low noise amplifier in accordance with a second embodiment of the present invention;

FIG. 11 is a Smith's chart showing points of Γ_(opt), G_(max) and S₁₁ depending on a feedback impedance of a common-gate inductive parallel feedback (CGPF) at 6GHz;

FIG. 12 is a circuit diagram of an active device of a low noise amplifier in accordance with a third embodiment of the present invention;

FIG. 13 is a Smith's chart showing circles of constant noise figures, and points of G_(max) of CCPF+CGPF and Γ_(opt) with respect to the 1.85nH local feedback inductance and 1.8KΩ wideband feedback resistance at 12GHz;

FIG. 14 is a circuit diagram of an active device of a low noise amplifier in accordance with a fourth embodiment of the present invention;

FIG. 15 is a Smith's chart showing points of Γ_(opt), G_(max) and S₁₁ with respect to a feedback inductor of CGSF at 6GHz;

FIG. 16 is a circuit diagram of an active device of a low noise amplifier in accordance with a fifth embodiment of the present invention;

FIG. 17 is a Smith's chart showing points of Γ_(opt), G_(max) and S₁₁ depending on a short feedback inductance of a common gate port of CSSL+CGPL at 6GHz;

FIG. 18 is a circuit diagram of an active device of a low noise amplifier in accordance with a sixth embodiment of the present invention;

FIG. 19 is a circuit diagram of an active device of a low noise amplifier in accordance with a seventh embodiment of the present invention;

FIG. 20 is a circuit diagram of an active device of a low noise amplifier in accordance with a eighth embodiment of the present invention;

FIG. 21 is a Smith's chart showing points of G_(max) of CCPF+CGPF and Γ_(opt), and circles of constant noise figures with respect to the 4K Ω feedback resistance and 1.7KΩ load resistance at 1 GHz

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

In FIG. 8, the active device of the low noise amplifier according to a first embodiment of the present invention is constituted by transistors M1 and M2 connected between a signal input and output stages in a cascode, and a feedback resistor R1 connected between the signal input and output stages. This is called a cascode resistive parallel feedback (CCPF) structure. This structure utilizes intrinsic advantages of the cascode structure, such as a higher gain, a wider bandwidth. Also, the advantages of the resistive parallel feedback structure having a better linearity, more stability and insensitivity against changes in parameters. Further, the noise and input stage power matching can be achieved by selecting the feedback resistor. The points of Γ_(opt) (the optimum noise matching source reflectivity) and G_(max) (the maximum available power gain matching source reflectivity) risen with the feedback resistance of 1.5KΩ are displayed in the Smith's chart shown in FIG. 9.

FIG. 9 shows points of Γ_(opt) G_(max) and S₁₁ depending on the feedback resistance of a cascode resistive parallel feedback at 4.5GHz. In FIG. 9, circles depicted by solid lines represent impedance circles, circles depicted by dot lines represent admittance circles, the values of the abscissa are real numerical values of the impedance and admittance, and the values along the circumference are imaginary numerical values thereof.

FIG. 10 is a circuit diagram of an active device for a low noise amplifier according to a second embodiment of the present invention, which is constituted by a transistor M3 between signal input and output stages and an inductor L1 connected between the input and output stages. This is called a common gate inductive parallel feedback CGPF structure. It is well known that CG has larger NF_(min), smaller gain and poorer stability than CS and is not appropriate for the low noise amplifier. However, the inductive parallel feedback structure makes NF_(min) smaller and gain larger, together with the unconditional stability. The inductive parallel feedback play a role to remove the capacitance C_(ds) between drain and source. In addition, as shown in FIG. 11, G_(max) can be made to be much closer to Γ_(opt). The requested inductance figure is approximately given by L_(fb) ≡1/(ωC_(ds)) where ω is angular frequency. Thus, the more the frequency and the width of the device is increased, the more this technique can be practical.

FIG. 11 shows impedance/admittance mapping of Γ_(opt), and G_(max) and points of Γ_(opt), G_(max) and S₁₁ depending on the feedback inductor of a common-gate inductive parallel feedback (CGPF) at 6GHz. In FIG. 11, circles depicted by solid lines represent impedance circles, the values of the abscissa are real numerical values of the impedance, and the values along the circumference are imaginary numerical values thereof. Rectangles are values of G_(max) and a plus (+) sign represents a value of Γ_(opt) , respectively. From FIG. 11, it is understood that the points of Γ_(opt) and G_(max) are closest at the inductor (L) figure point of 7.5.

FIG. 12 is a circuit diagram of an active device for a low noise amplifier according to a third embodiment of the present invention, which is constituted by transistors M4 and M5 connected between an input stage and an output stage in a cascode, a resistor R2 connected between the input stage and the output stage, and an inductor L2 connected to the transistor M5 in parallel. The structure shown in FIG. 12 is one produced by combining advantages of CGPF and CCPF and is to be called a cascode resistive parallel feedback structure with a common-gate inductive parallel feedback (CCPF+CGPF). Also, this structure is more useful in a higher frequency (X band). This is because the noise contribution in the CGPF may be sharply reduced from the CG stage becoming greater as the frequency increases.

FIG. 13 shows circles of constant noise figures, and points of G_(max) of CCPF+CGPF and Γ_(opt) with respect to the 1.85nH local feedback inductance and 1.8KΩ wideband feedback resistance at 12GHz. In FIG. 13, circles depicted by solid lines represent impedance circles, the values of the abscissa are real numerical values of the impedance, and the values along the circumference are imaginary numerical values thereof. Rectangles represent values of G_(max) , plus (+) signs represent values of Γ_(opt), and the circles centering at Γ_(opt) represents noise figure circles, respectively.

FIG. 14 is a circuit diagram of an active device for a low noise amplifier according to a fourth embodiment of the present invention, which is constituted by transistors M6 and M7 connected between an input stage and an output stage in a cascode, an inductor L3 connected between source and ground of the transistor M6, and a resistor R3 connected between the output stage and the ground. This is to be called a cascode inductive series feedback (CCSF) structure. It is reported that simultaneous matching of Γ_(opt) and S₁₁ * can be obtained by using the inductive series feedback and common source CS and the appropriate load, instead of G_(max). However, the gain becomes considerably small due to a series feedback and small load impedance. Also, poor output VSWR is unavoidable. Further, as the frequency is increased, the G_(max) points are quite different from S₁₁ * due to S₁₂. The cascode can solve such problems because the gain of the cascode is far greater than that of the CS and the output load does not affect on the input matching due to much smaller S₁₂ of the cascode.

FIG. 15 shows points of Γ_(opt), G_(max) and S₁₁ with respect to the feedback inductor of CGSF at 6GHz. In FIG. 15, circles depicted by solid lines represent impedance circles, the values of the abscissa are real numerical values of the impedance, and the values along the circumference are imaginary numerical values thereof. Rectangles represent values of G_(max), and plus (+) signs represent values of Γ_(opt), respectively. From FIG. 15, it is understood that the noise and input power simultaneousness matching occurs at 0.8nH series feedback.

FIG. 16 is a circuit diagram of an active device for a low noise amplifier according to a fifth embodiment of the present invention, which is constituted by transistors M8 and M9 connected between an input stage and an output stage in a cascode, an inductor L4 connected between source and ground of the transistor M8, and an inductance L5 connected to the transistor M9 in parallel. This is produced by combining a common source inductive series feedback (CSSL) and a common gate inductive parallel feedback (CGPF) and is to be called a CSSL+CGPF structure. In other words, this structure is produced by utilizing the advantages of the common source inductive series feedback and a common gate inductive parallel feedback. That is to say, the noise and input power simultaneousness matching is obtained by inductive series feedback. Also, the minimum noise added from the common-gate (CG) stage and good stability can be obtained by the inductive parallel feedback.

FIG. 17 shows points of Γ_(opt), G_(max) and S₁₁ depending on the short feedback inductance of a common gate stage of CSSL+CGPL at 6GHz. In FIG. 17, circles depicted by solid lines represent impedance circles, the values of the abscissa are real numerical values of the impedance, and the values along the circumference are imaginary numerical values thereof. Rectangles represent values of G_(max), and plus (+) signs represent values of Γ_(opt), respectively. From FIG. 17, it is understood that the points of G_(max) and Γ_(opt) are closest at 2nH-6nH.

FIGS. 18 through 20 illustrate circuit diagrams which embody the CCPF, the CCSF and the NMOS transistor of the fifth embodiment into bipolar transistors, respectively.

The following tables 1 to 3 show at 2(B=f_(T) /f=12), 6(B=f_(T) /f=4) and 12(B=f_(T) /f=2) GHz the compared performances of the active device of the low noise amplifier according to the present invention in view of common-source (CS) structure (FIG. 2), common-source resistive load (CSRL) structure (FIG. 3), common-source inductive series feedback (CSSL) structure (FIG. 4), common-source inductive series feedback and resistive load (CSSF) structure (FIG. 5), common-gate (CG) structure (FIG. 6) and cascode structure (FIG. 7). When a selected device is a GaAs MESFET, it has f_(T) value of 24 GHz, and when another selected device is a silicon npn bipolar transistor, it has f_(T) value of 10 GHz. The items in each first row of the following table 1 to 3, show stability factor (K) for each structure, the maximum available power gain (MAG), the minimum noise figure NFmin, the minimum noise measure (M_(min)), and the input voltage standing wave ratio (VSWR) when the input noise is matched and the output gain is matched, respectively. These values are obtained by using an EEsof's simulator (EEsof's Libra™). Also, from the tables, it should be noted that the larger K than 1, the smaller NF_(min), the smaller M_(min) and the closer VSWR to 1, the better the low noise amplifier is.

                  TABLE 1     ______________________________________     Structure    K      MAG (dB)  NF.sub.min                                         M.sub.min                                              VSWR     ______________________________________     CS           0.133  17.343    0.570 0.144                                              --     CSRL (10Ω)                  1.048  15.998    1.313 0.420                                              23.20     CSSL (4 nH)  1.004  12.625    0.543 0.144                                              3.35     CSSF (4.2 nH & 600Ω)                  1.273  9.699     0.668 0.187                                              1.54     CG           0.963  9.370     0.526 --   --     CGPF (75 nH) 1.005  9.106     0.516 0.144                                              1.36     cascode      0.099  26.711    0.626 --   --     CCSF (2.4 nH & 1.2KΩ)                  2.361  17.662    0.661 0.166                                              1.84     CCPF (2KΩ)                  1.077  15.808    1.478 0.417                                              1.31     CCPF + CGPF (2KΩ &                  1.082  15.655    1.477 0.417                                              1.33     75 nH)     CSSL + CGPF (2 nH &                  1.599  17.472    0.610 0.154                                              1.45     10 nH)     ______________________________________

                  TABLE 2     ______________________________________     Structure    K      MAG (dB)  NF.sub.min                                         M.sub.min                                              VSWR     ______________________________________     CS           0.274  12.604    0.870 0.244                                              --     CSRL (20Ω)                  1.032  11.511    1.652 0.613                                              11.80     CSSL (0.6 nH)                  1.018  10.712    0.836 0.244                                              3.80     CSSF (0.6 nH & 100Ω)                  2.500  4.725     1.538 0.649                                              1.36     CG           0.741  8.251     0.921 --   --     CGPF (7.5 nH)                  1.031  8.797     0.831 0.244                                              1.36     cascode      0.070  20.856    1.284 --   --     CCSF (0.6 nH &                  3.895  10.938    1.651 0.504                                              1.36     400KΩ)     CCPF (1.7KΩ)                  1.074  15.313    2.047 0.621                                              1/45     CCPF + CGPF (1.8KΩ                  1.185  13.903    1.986 0.605                                              1.42     & 7.5 nH)     CSSL + CGPF (0.6 nH                  2.287  14.527    1.375 0.387                                              1.84     & 6 nH)     ______________________________________

                  TABLE 3     ______________________________________                          MAG     Structure    K       (dB)    NF.sub.min                                        M.sub.min                                              VSWR     ______________________________________     CS           0.496   9.780   1.320 0.437 --     CSRL (50Ω)                  1.083   8.023   1.974 0.878 6.80     CSSL (0.25 nH)                  1.031   8.420   1.313 0.437 3.10     CSSF (0.25 nH & 150Ω)                  1.962   3.869   1.967 0.979 1.24     CG           0.438   6.401   1.722 --    --     CGPF (1.85 nH)                  1.020   8.721   1.386 0.437 1.45     cascode      -0.287  16.180  2.643 --    --     CCSF (0.25 nH &                  2.688   8.744   3.592 1.490 1.36     300KΩ)     CCPF (R.sub.fb = 700Ω &                  1.324   9.576   3.812 1.580 1.00     R.sub.L = 600Ω)     CCPF + CGPF (1.8KΩ                  1.576   11.236  2.928 1.043 1.36     & 1.85 nH)     CSSL + CGPF (0.2 nH                  5.078   9.092   2.862 1.071 1.54     & 1.4 nH)     ______________________________________

                  TABLE 4     ______________________________________                        MAG     Structure  K       (dB)    NF.sub.min                                      Rn   M.sub.min                                                VSWR     ______________________________________     CE         0.408   18.908  2.550 0.500                                           0.817                                                --     CERL (60Ω)                1.001   18.722  2.609 0.512                                           0.864                                                11.80     CESL (1.3 nH)                1.003   15.700  2.509 0.445                                           0.817                                                4.10     CESF (1.6 nH &                1.439   11.500  2.564 0.451                                           0.868                                                1.45     200Ω)     CB         0.215   16.977  2.614 0.501                                           --     cascode    -1.351  35.885  2.628 0.505     CCSF (1 nH &                6.045   22.991  2.648 0.470                                           0.844                                                1.54     600Ω)     CCPF (R.sub.fb = 4KΩ                1.107   22.227  2.722 0.506                                           0.873                                                1.24     & R.sub.L = 1.7KΩ)     CESL + CBPL                2.795   18.795  2.609 0.472                                           0.835                                                1.24     (0.8 nH & 5 nH)     ______________________________________

From the above tables, it is understood that the minimum noise characteristic, i.e., NF_(min) of CCPF shown in FIG. 9, is slightly increased at a drain node together with a stabilizing resistance, compared to a simple circuit structure such as the CS structure. This is because of the noise added from the feedback resistance and the common gate CG at the high frequency (C and X bands) and that added from the feedback resistance at the low frequency (L band). In order to reduce NF_(min) of CCPF, a much greater matching resistance should be used or the noise added from CG stage should be reduced considering the interstage matching between CS and CG. Thus, the structures shown in FIGS. 10 and 12 are produced.

It is well known that CG has greater NF_(min), smaller gain, poorer stability than CS. However, the inductive parallel feedback structure makes NF_(min) smaller and gain larger, together with unconditional stability. The inductive parallel feedback play a role to remove the capacitance between drain and source C_(ds). Further, as shown in FIG. 11, G_(max) can be made to be much closer to Γ_(opt). The requested inductance figure is roughly given by L_(fb) ≡ 1/(ω² C_(ds)) where co represents an angular frequency. Thus, the structure shown in FIG. 10 can be more practical as the frequency is increased and the gate width of the device is increased. The normalized noise resistance of CGPF is smaller than that of CS. This means that the radii of the circles having constant noise characteristics of CGPF are larger, which allows CGPF to offer excellent noise measuring performance together with the simultaneous noise, input power matching and unconditional stability (to be referable to table 1 to 3). However, the producibility of the structure is a key point due to comparatively great variation of C_(ds), and the output power matching is rather difficult due to large output impedance.

In addition to the reduction of NF_(min) of the CG stage, the local inductive parallel feedback structure allows the use of much greater feedback resistance for the simultaneous matching, as shown in the table 3. The minimum noise measure M_(min) of the CCPF+CGPF structure is much lower than that of the CCPF structure at 12GHz.

The minimum noise measure M_(min) of the CCSF+CCPF structure is much smaller than that of the CSSF structure at 2 and 6GHz, together with the CSSF structure, but is not like that at 12GHz. This is because the noise added from the CG stage is more increased according to the increase of the frequency. The structure for reducing the noise is shown in FIG. 16. The M_(min) of this structure is very excellent in all the microwave ranges. However, the disadvantages of this structure are in that two inductors are required and a chip size is considerably increased accordingly.

As the result, though the respective structure is good enough to be used as the low noise frequency active device, each has some disadvantages.

Now, let us consider which structure is the most appropriate with respect to a given frequency band, i.e., L (2GHz), C (6GHz) and X (12GHz) bands.

First, with respect to the L band, the structure having the VSWR characteristic smaller than 2 with the smallest M_(min) in the Table 1 is the CGPF structure. However, in this structure, the requested inductance is 75nH, which is too large to be embodied by a monolithic type. The candidates having the next smallest M_(min) are the CSSL+CGPF and CCSF structures, each having a similar minimum noise measure performance. Considering the bandwidth, linearity, stability and insensitivity to the parameter change, although these structures have a slightly larger NF_(min), the CCPF and CCPF+CGPF structures are also reasonably good techniques. As a whole, when a 0.5 μm MESFET is used, the CCSF and CSSL+CGPF structures seem to be the best choice. For an LNA adopting an NPN type BJY, the M_(min) of the CCPF structure is almost the same as those of others. This is because the increase in the MF_(min) is negligible due to the large gain and the large feedback resistance of the CE stage. Further, the points of Γ_(opt) and G_(max) are close to 50Ω as shown in FIG. 21. Thus, the CCPF structure is the best for the application of the L band using the silicon NPN type BJT(see Table 4).

Next, with respect to C and X bands, in Tables 2 and 3, the structure having the VSWR smaller than 2 and the lowest M_(min) is the CGPF structure, where the requested inductance values are 7.5nH and 1.85nH at 6GHz and 12GHz, respectively, to thereby be embodied by the monolithic type. The CSSL+CGPF, CCSF, CCPF and CCPF+CGPF structures exhibit considerably good noise measurements together with the unconditional stability and producibility. Particularly, in the X band, among the structures using the cascode, the CCPF+CGPF and CSSL+CGPF structures exhibit better noise measure performances than the CCSF and CCPF structures. This means that the common-gate inductive parallel feedback plays an important role in increasing the noise measure performance at a higher frequency. In conclusion, if the unity for the Cds figure and feedback inductance is properly maintained, the CGPF structure is the best one at 6GHz and 12GHz, in view of the noise measurement performance as well as the noise and input power simultaneousness matching and unconditional stability. In addition to the CGPF structure, the CSSL+CGPF structure is the best one at 6GHz, and the CCPF+CGPF and CSSL+CGPF structures are the best ones at 12GHz. This is because the noise performance is not sensitive to the change in the feedback inductance in the CCPF+CGPF nor CSSL+CGPF structure, while being sensitive in the CGPF structure.

Therefore, the low noise amplifier according to the present invention allows the points of Γ_(opt) and G_(max) to be closer to each other so that the noise and input gain simultaneousness matching is performed, thereby improving the performance.

While the present invention has been described and illustrated with reference to preferred embodiments thereof, it is to be readily understood by those skilled in the art that the present invention is not limited to the embodiments, and various changes and modifications can be made therein without departing from the spirit and scope of the invention defined in the appended claims. 

What is claimed is:
 1. A low noise amplifier comprising:an input matching means of an input stage and an output matching means of an output stage; a common source transistor and a common gate transistor serially connected between said input matching means and said output matching means; a feedback resistor connected between said input matching means and said output matching means; and an inductor connected between the common point of said common source transistor and common gate transistor and said output matching means.
 2. A low noise amplifier comprising:an input matching means of an input stage and an output matching means of an output stage; a common source transistor and a common gate transistor serially connected between said input matching means and said output matching means; a first inductor connected between a source and a ground of said common source transistor; and a second inductor connected between the common point of said common source transistor and common gate transistor and said output matching means.
 3. A low noise amplifier comprising:an input matching means of an input stage and an output matching means of an output stage; a common emitter transistor and a common base transistor connected in serial between said input matching means and said output matching means; a first inductor connected between an emitter and a ground of said common emitter transistor; and a second inductor connected between the common point of said common emitter transistor and common base transistor and said output matching means. 